Device and method for connecting a medical instrument to a position-detecting system

ABSTRACT

The invention relates to a device for connecting a medical instrument to a position-detecting system, the device having a localization element. The medical instrument has an instrument shaft, an instrument tip and an operating point. At least one localization element for determining position information for the device within a coordinate system of the position-detecting system can be provided on the device, the device having at least one retaining means for attaching the localization element to the medical instrument.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 14/903,381, having a filing date of Jan. 7, 2016 under 35 U.S.C. § 371(c), which is the U.S. National Stage of International Application Number PCT/EP2014/065030 filed on Jul. 14, 2014 which application claims priority under 35 U.S.C. § 119 to German Patent Application No. 102013214067.3 filed on Jul. 17, 2013, which applications are hereby incorporated by reference in their entirety.

TECHNICAL FIELD

The invention relates to a device for connecting a medical instrument, in particular a medical instrument for invasive surgical interventions, to a location-detecting system, the medical instrument having an instrument shaft, an instrument tip and a working point.

BACKGROUND

In this context, a location-detecting system is intended to mean a system which delivers location information to a medical instrument. The location information is useful in order to use an instrument in combination with imaging devices such as topographs, tomographs or tomographically obtained image data. In this context, location information is intended to mean the position and the orientation of the medical instrument in relation to a reference coordinate system. A reference coordinate system is a coordinate system of a location-detecting device or of a location-detecting system. The location information may be acquired by means of a location-detecting device with a corresponding measuring system.

During the conduct of invasive surgical interventions, preoperatively obtained image data of the patient, for example computed tomography recordings, are often used as planning data. Furthermore, it is usual to record images of the patient intraoperatively, i.e. with an endoscope, and to represent these together with the preoperatively compiled data on a monitor, respectively as an individual image or overlaid. In this way, for example, tissue to be removed or nerve paths or vessels lying in the operation region and potentially at risk from the surgical intervention can be made more clearly visible to the surgeon. This representation of the image data can therefore assist the surgeon to use the medical apparatus employed during the operation as efficiently as possible and with the least possible damage to the patient's surrounding tissue. In this case, the surgeon must first navigate the medical instrument as accurately as possible along a determined path into a usually preoperatively established intervention region in the patient's body and carry out the operative measures, for example the removal of tissue parts, as precisely as possible in the intervention region. Following the operative measures, the medical instrument must be navigated back out of the patient's body while being monitored. Therefore, invasive surgical interventions often require a high degree of accuracy of the location information of medical instruments which is being ascertained.

Furthermore, the mental correlation between the image data provided and the control of the medical instruments can easily lead to orientation problems for the surgeon and therefore to operational mistakes and/or lengthening of the operation.

For this reason, position-detecting or location-detecting systems are regularly used as an orientation aid for the surgeon during the operation, for example in order to assist navigation of medical instruments, in particular surgical instruments. During the operation, such systems record the coordinate transformation between the patient and at least one medical instrument. In many location-detecting systems, location information of a multiplicity of different medical instruments can be determined. The location information obtained is generally visualized on a monitor together with the preoperative planning data and/or the intraoperative image data. To this end, localization elements, the location information of which is recorded by a measuring system as a location-detecting device, are arranged at particular positions of the patient as well as on the medical instruments. In this way, the localization elements location information of the in the location-detecting system can initially be determined.

Such location-detecting systems may for example comprise optical, ultrasound-assisted or electromagnetic localization elements. For example, electromagnetic location-detecting systems which have a field generator are known. The field generator generates a generally alternating AC electric field in an operation region. Localization elements which have coils are arranged on a medical instrument to be navigated in this operation region. The AC electromagnetic field induces in these coils characteristic currents as a function of the orientation of the respective coil relative to the AC electromagnetic field, and the location information of the coils can be determined from these currents.

It is furthermore known to provide various medical instruments, for example pointer instruments, siphons, forceps, needles, scalpels, electrotomes, cauterizers, etc., with localization elements for determining the location information for such a location-detecting system and to register the respective medical instrument in the location-detecting system. During the registration of the medical instrument, the location of a reference point—usually the working point of the instrument tip—relative to the localization element arranged on the medical instrument is calibrated and transmitted to the location-detecting system. The location of the reference point and orientation of the medical instrument in the coordinate system of the location-detecting system are therefore known and can be represented on the monitor together with the existing image data.

A requirement for registration of a medical instrument in a location-detecting system is that the medical instrument has at least one localization element. However, there are many medical instruments which do not have such a localization element and cannot therefore be used in a location-detecting system.

SUMMARY

It is therefore an object of the present invention to provide a device for connecting a medical instrument to a location-detecting system, so that medical instruments which do not have their own localization element can be registered in a location-detecting system, in order that location information of the respective medical instrument can be determined by the location-detecting system and, for example, can be represented on a monitor.

According to the invention, the object is achieved by a device having a localization element for connecting a medical instrument to a location-detecting system, the medical instrument having an instrument shaft, an instrument tip and a working point. At least one localization element for determining location information, for instance orientation and position, of the device relative to a reference point can be arranged on the device. The device furthermore has a holding means for fastening to the medical instrument.

Preferably, the holding means has an instrument holder, at least a subsection of the medical instrument being engageable with the instrument holder and being fastenable to the instrument holder by at least one fixing means. The instrument holder may be for example, configured in the shape of a cup or a cylinder. Preferably, the instrument holder is configured in order to hold a subregion of the medical instrument. Furthermore, the instrument holder can preferably be fitted onto the medical instrument on the instrument tip side, the distal end of the medical instrument, and can be displaced along an instrument longitudinal axis on the instrument. Preferably, the instrument holder is fastened to the instrument shaft by the fixing means.

Preferably, the fixing means comprises a screw. The screw can for example be screwed into the device so that, as a result, its preferably flattened screw tip presses against an instrument shaft section which the instrument holder comprises, so as to hold the medical instrument in the instrument holder.

In a preferred embodiment of the invention, the fixing means has a clamping device, in order to hold the medical instrument in the instrument holder. The clamping device may for example have clamping jaws, which are to be clamped to the medical instrument by means of a screw mechanism.

Preferably, the device has a sensor holder which can hold the localization element. In this case, both embodiments in which the localization element is to be held reversibly and embodiments in which the localization element is to be held irreversibly in the sensor holder are provided.

In a preferred embodiment of the invention, the sensor holder and the localization element have guide means, by means of which the sensor element and localization element can be connected to one another, or engaged with one another, in such a way that the sensor holder and the localization element can be displaced relative to one another on a guide path. In this case, for example, the sensor holder may have a rail-shaped part and the localization element may have a corresponding carriage-shaped part. As an alternative the sensor holder may have a carriage-shaped part and the localization element may have a rail-shaped part.

Preferably, the guide means of the sensor holder and/or of the localization element are configured in such a way that a relative movement of the sensor holder and the localization element is possible only as far as a defined point on the guide path. To this end, at least a part of the guide path may, for example, have a tooth or a stop.

Preferably, the guide means of the sensor holder and/or of the localization element have a retaining means with a spring element, the localization element being fixable in a predefined position on the guide path by the retaining means. The retaining means is preferably configured to trigger the fixing by the movement of the localization element along the guide path. To this end, the rail-shaped part of the guide means may for example have a groove, and the carriage-shaped part of the guide means may have a resiliently held wedge, which can be tilted by the spring force into the groove of the rail-shaped part and therefore cause the fixing.

In a preferred embodiment of the invention the localization element is arranged firmly on the holding means. Removal of the localization element from the holding means is not provided in this embodiment.

Preferably, the device has an outer surface with an essentially cylindrical shape. The outer surface may, however, also be configured with an essentially cuboid or quadrilateral shape.

In an advantageous configuration of the invention, the device is configured in order to be connected to a control unit of the location-detecting system by a cable, in order to transmit signals from the localization element to the control unit of the location-detecting system. To this end, the device may have a cable or a connection for a cable, for example a jack socket. As an alternative, the device may send the signals of the localization element to the control unit of the location-detecting system via a radio device. In such a wireless embodiment, the device preferably has means for providing a supply current, for example an accumulator or battery.

Preferably, the holding means has a channel extending in the longitudinal direction of the holding means. The channel is open at both end sides of the holding means, so that at least the instrument tip of the medical instrument can be passed through the channel.

Furthermore, preferably, the channel has an essentially oval cross section. The advantage of the oval cross section is, in particular, that the holding means can be displaced along a curved region of an instrument longitudinal axis of a flexurally stiff and curved instrument tip.

According to the invention, a localization element held on the medical instrument by the device can be calibrated to the working point of the medical instrument. This may, for example, be done by a method in which a reference point is approached with the working point of the instrument tip, and at the same time the location and orientation of the localization element held on the instrument are detected. When the reference point is reached, the localization element is therefore calibrated to the instrument tip. Preferably, at the moment when the working point of the instrument tip reaches the reference point, the working point is automatically calibrated. This is, for example, made possible by a pressure sensor at the reference point, or an electrical circuit which is closed by contact of the working point of the instrument tip with the reference point. As an alternative or in addition, the method may provide that, as a starting condition for calibration of the localization element to the instrument tip, a check is made whether the reference point to be approached lies within a search sector which relates to the localization element held/to be held on the medical instrument. The search sector may be differently specifiable depending on the instrument. Preferably, the search sector is configured in the shape of a wedge. The wedge axis lies, coaxially with a longitudinal axis of in particular, the instrument tip and/or coaxially with a channel of the holding means, intended for the instrument to be passed through. The wedge tip preferably points toward and/or preferably lies at the center of the localization element. Preferably, the search sector is specified in such a way that an instrument tip lies inside the search sector when the localization element is held on the medical instrument.

As an alternative (or in addition), the device may also be configured in such a way that automatic calibration is carried out when the working point (i.e. for example the instrument tip) remains at the reference point for a predetermined time. After successful calibration, the location data of the working point of the instrument tip may be determined by the location-detecting system by means of the location information provided by the respective localization element.

Particularly preferably, the reference point is arranged. on a localization element which is connected to the location-detecting system and is registered. The localization element may likewise be the localization element of an instrument, so that two medical instruments within the can easily be registered at the same time location-detecting system. The exact position of the reference point within the location-detecting system can therefore be determined easily. The reference point arranged on the localization element is suitable for calibrating a new instrument, equipped with a further localization element, to the working point of the instrument. Such a calibration process may therefore also be carried out intraoperatively. A further or alternative reference point may be a localization element which is arranged on the patient and is location information configured for determining the of the patient within the location-detecting system.

It is particularly preferred for the reference point to be configured as a depression or an elevation (for example on a second instrument), in order to allow self-centering of a corresponding medical instrument at the reference point. A depression-shaped reference point is particularly suitable for self-centering of an instrument having a tip-shaped instrument tip with the reference point, since the instrument tip can be introduced into the depression and therefore guided along an inner surface of the depression to the midpoint thereof. Furthermore, preferably, the midpoint of the depression has a further local indentation with a smaller depression radius, into which an instrument tip can be introduced. The approaching of the depression midpoint with the instrument tip is therefore further facilitated. A reference point configured as an elevation is particularly suitable for the calibration of instruments which comprise a tubular instrument tip having an inner channel, for example siphons.

Preferably, the localization element has a sensor coil. Sensor coils are suitable for use in position-detecting systems having an AC electromagnetic field generated by a field generator.

Particularly preferably, the location-detecting system is configured in order to register and simultaneously manage a plurality of localization elements. The location information of a plurality of medical instruments equipped with localization elements can therefore simultaneously be determined as well as graphically and/or digitally represented. The management of a plurality of localization elements may, for example, be carried out by means of multiplexing. In the case of multiplexing, the registered localization elements are driven at a predetermined clock rate so that only one particular localization element is respectively driven by the location-detecting system at one time. In this case, it is advantageous that the location-detecting system can discriminate between active and inactive instruments. Inactive instruments may therefore be blocked out by the location-detecting system, for example by a corresponding filter, or the corresponding localization elements may be deactivated in order to increase the stability of the signals of the localization elements of the active instruments.

To this end, the multiplexer may, for example, be configured so that initially all the localization elements are activated and driven at the predetermined clock rate. As soon as a localization element of an instrument arranged in an operation region is detected, the remaining localization elements are deactivated or the corresponding instruments are blocked out until the active instrument leaves the operation region again. For the residence time of the active instrument in the operation region, the corresponding localization element is preferably detected continuously by the location-detecting system. The location-detecting system may preferably be configured manually in order to detect a larger number than one instrument, for example two, simultaneously in the operation region by means of multiplexing, and only to deactivate the remaining localization elements or block out the corresponding instruments when this predetermined number of active instruments arranged in the operation region is reached.

In an alternative configuration of the invention, a device may be provided in order to unblock a particular instrument manually and/or activate the respective localization element.

This may, for example, be done by means of a pressure sensor arranged on the instrument handle, which automatically detects when the instrument is being held in the hand. The control may be configured in such a way that the corresponding instrument remains active and unblocked until another instrument is activated, or unblocked. The system may be configured in order to manage a plurality of active instruments simultaneously. Furthermore, the system may be configured in order not to automatically deactivate or block out an activated instrument arranged in the operation region. This ensures that an instrument, for example, remains active for at least as long as it is arranged inside the operation region.

As an alternative, the instrument rack may, for example, be configured in order to detect inactive instruments which are placed on an instrument rack and forward this information to the location-detecting system, so that the location-detecting system deactivates or blocks out these inactive instruments.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be explained in more detail with the aid of an exemplary embodiment with reference to the figures. In the figures:

FIG. 1 shows a schematic side view of a medical instrument with localization element fitted thereon;

FIG. 2 shows the view of the medical instrument of FIG. 1, a further localization element being arranged on the instrument tip; and

FIG. 3 shows a front view of a control unit with localization element is coupled thereto, a localization element being arranged on a medical instrument.

DETAILED DESCRIPTION

The medical instrument 10 represented in FIG. 1 has an instrument shaft 12 and an instrument tip 14. The instrument shaft 12 has a distal shaft region 12 a and a handle region 12 b, a proximal tip region 14 b of the instrument tip 14 being arranged on the distal shaft region 12 a. The instrument shaft 12 may be configured in one piece or in several pieces, separately, with the instrument tip 14.

The instrument tip 14 has a distal tip region 14 a, on the end of which facing away from the proximal tip region 14 b a working point 16 is arranged. The instrument tip 14 furthermore has a curved region 15, which is next to the distal tip region 14 a. In alternative embodiments, the instrument tip 14 may also have curvatures stronger (smaller radius) than represented, or further curvatures. The instrument shaft 12 and the instrument tip 14 have an essentially round cross section.

A localization element 20 is arranged next to the distal shaft region 12 a on the proximal tip region 14 b of the instrument tip 14. According to the embodiment shown, the distal shaft region 12 a has a conical taper extending in the direction of the instrument tip 14, which can be engaged at least partially with the localization element 20. The localization element 20 is secured against displacement along a longitudinal axis of the instrument tip 14 by means of a clamping screw 22 on the proximal tip region of the instrument tip. Furthermore, the localization element 20 has a cable 18 for connection to a control unit 26 shown in FIG. 3.

By means of reference point 24, the localization element 20 can be calibrated to the working point 16 of the medical instrument 10 for calibration. The calibration process may be carried out essentially automatically by the operator bringing the working point 16 of the medical instrument 10 into contact with the reference point 24 and, for example, maintaining this state for a predetermined time—for example from 1 to 2 seconds. As an alternative, for example, the reference point 24 may have a sensor (not represented here) which detects the moment of contact of the working point 16 with the reference point 24 and forwarding a corresponding signal to the control unit 26, so that the control unit 26 can record the location data of the localization element 20 at the time of contact of the working point 16 with the working point 24 and therefore complete the calibration measurement. After calibration has been carried out, the location information of the working point 16 of the medical instrument in an operation region can be determined by means of the sensor signals transmitted from the localization element 20 to the location-detecting system.

As shown by FIG. 2, a plurality of localization elements 20 may be arranged according to the invention on a medical instrument 10. One localization element 20 is already arranged in this view on the proximal tip region 14 b of the instrument tip 14 as previously in FIG. 1, while a further localization element 20 is furthermore held on the distal tip region 14 a and can be displaced toward the proximal tip region 14 b along the tip longitudinal axis. The advantage of using a plurality of localization elements 20 on a medical instrument 10 is that the localization elements 20 provide mutually complementary and partially redundant location information, and measurement variations or measurement errors can therefore be detected by the control unit 26 of the location-detecting system.

Likewise shown in FIG. 2 is a wedge-shaped search sector 27. The search sector 27 relates to the localization element 20 held on the medical instrument 10 in the proximal tip region 14 b. The wedge axis z lies coaxially with the longitudinal axis of the instrument tip 14. The wedge tip of the wedge-shaped search sector 27 points toward and lies at the center of the localization element 20 which is held in the proximal tip region 14 b. The wedge-shaped search sector 27 therefore starts from the localization element 20 and extends and widens in the distal direction. Preferably, it ends at a defined distance from the localization element 20 and therefore defines a search space delimited on all sides. The search sector 27 is in the present case specified in such a way that an instrument tip 14 lies inside the search sector 27 when the localization element 20 is held on the medical instrument 10. The search sector 27 may also have a different shape, and need not be wedge-shaped. The purpose of the search sector 27 is to trigger automatic calibration only when it is found that the position data of the reference point 24, detected by the location-detecting system, lie inside the position data space (set of position data falling within the search sector) spanned by the search sector 27. In embodiments of the medical instrument 10 with an instrument shaft 12 and instrument tip 14 which can be separated from one another, the localization element 20 may be configured in order to be fitted directly onto the proximal tip region 14 b when the instrument shaft 12 and the instrument tip 14 are separated from one another. After the fitting of the localization element 20, the instrument shaft 12 and the instrument tip 14 may be reconnected to one another.

As an alternative, embodiments are provided in which the localization element 20 can be fitted onto the instrument shaft 12. To this end, in principle, the same holding means as for fastening to the instrument tip 14 are suitable, the dimensions of the instrument shaft 12 needing to be taken into account.

According to the invention, a control unit 26 (as represented in FIG. 3) may be connected to a plurality of localization elements 20, preferably in each case by a cable 18. In this case, one or more localization elements 20 may respectively be arranged on a medical instrument 10. Furthermore, the localization elements 20 may be arranged on different medical instruments 10, only one medical instrument 10 being shown in FIG. 3. The control unit 26 may have a filter in order to block out inactive instruments 10, which are arranged for example on an instrument rack (not represented). In this way, the stability of the signals of the active instruments 10 is increased.

LIST OF REFERENCES

-   10 medical instrument -   12 instrument shaft -   12 a distal shaft region -   12 b handle region -   14 instrument tip -   14 a distal tip region -   14 b proximal tip region -   15 curved region -   16 working point -   18 cable -   20 localization element -   22 clamping screw -   24 reference point -   26 control unit -   27 search sector -   Z cone axis 

1. A device having a localization element for connecting a medical instrument to a location-detecting system, the medical instrument having an instrument shaft, an instrument tip and a working point, wherein at least one localization element for determining location information of the device within a coordinate system of the location-detecting system can be arranged on the device, wherein the device has at least one holding means for fastening to the medical instrument, and the localization element has a sensor coil for use in position-detecting systems with an alternating electromagnetic field generated by a field generator, and the device can be connected by a cable to a control unit of the location-detecting system in order to transmit signals from the localization element to the control unit of the location-detecting system.
 2. The device as claimed in claim 1, characterized in that the holding means has an instrument holder, at least a subsection of the medical instrument being engageable with the instrument holder and being fastenable to the instrument holder by at least one fixing means.
 3. The device as claimed in claim 2, characterized in that the fixing means comprises a screw, which can be screwed into the device so that, as a result, its preferably flattened screw tip presses against an instrument shaft section which the instrument holder comprises, so as to hold the medical instrument in the instrument holder.
 4. The device as claimed in claim 2 or 3, characterized in that the fixing means has a clamping device.
 5. The device as claimed in one of the preceding claims, characterized in that the device has a sensor holder for holding the localization element.
 6. The device as claimed in one of claims 1 to 4, characterized in that the localization element is arranged irreleasably on the holding means.
 7. The device as claimed in one of the preceding claims, characterized in that the device has an essentially cylindrical outer surface.
 8. The device as claimed in one of the preceding claims, characterized in that the holding means has a channel extending in the longitudinal direction, the channel being open at both end sides of the holding means, it being possible to pass at least the instrument tip of the medical instrument through the channel.
 9. The device as claimed in claim 8, characterized in that the channel essentially has an oval cross section.
 10. The device as claimed in one of the preceding claims, characterized in that the device has a reference point with which an instrument tip of a further medical instrument can be automatically calibrated in the location-detecting system by bringing the instrument tip into contact with the reference point.
 11. The device as claimed in claim 10, characterized in that the reference point has a depression or an elevation, the reference point being arranged on a midpoint of the depression or elevation.
 12. A method with which a localization element held on the medical instrument by the device can be calibrated to the working point of the medical instrument, wherein during the method a reference point is approached with the working point of the instrument tip, and at the same time the location and orientation of the localization element held on the instrument are detected.
 13. The method as claimed in claim 12, wherein, at the moment when the working point of the instrument tip reaches the reference point, the working point is automatically calibrated, or automatic calibration is carried out when the working point remains at the reference point for a predetermined time.
 14. The method as claimed in claim 12 or 13, wherein the automatic calibration is made possible by a pressure sensor at the reference point, or an electrical circuit which is closed by contact of the working point of the instrument tip with the reference point.
 15. The method as claimed in one of claims 12 to 14, wherein as a starting condition for calibration of the localization element to the instrument tip, a check is made whether the reference point to be approached lies within a search sector which relates to the localization element held/to be held on the medical instrument. 